qcd phase diagrams via a nonperturbative...
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QCD Phase Diagrams via a Nonperturbative Approach
Yu-xin LiuDept. Phys., Peking Univ., China
1st Symposium on iHIC, Tsinghua University, April 8-10, 2018
OutlineI. IntroductionⅡ. DS Eqs. — A NPQCD Approach Ⅲ. CriteriaⅣ. Phase DiagramsV. Remarks
1
I. IntroductionStrong int. matter evolution in early universe can be attributed to QCD Phase Transitions
Items Influencing the Phase Transitions:Medium:Temperature T ,
Density ρ ( or µ ) Size
Intrinsic:Current mass,Coupling Strength,Color-flavor structu
••• •••
Phase Transitions involved:Flavor Sym. – F.S. BreakingDeconfinement–confinementDCS – DCSB
Chiral SymmetricQuark deconfined
χSB, Quark confined
sQGP
?
?
?
2
♠ The existence of the CEP and its locationhave been a key subject in the QCD PT
• (p)NJL model & others give quite large µEq/TE (> 3.0)
Sasaki, et al., PRD 77, 034024 (2008); 82, 076003 (2010); 82, 116004 (1010); 0).Costa, et al., PRD 77, 096001 (‘08); EPL 86, 31001 (‘09); PRD 81, 016007(‘10); Fu & Liu, PRD 77, 014006 (2008); Ciminale, et al., PRD 77, 054023 (2008); Fukushima, PRD 77, 114028 (2008); Kashiwa, et al., PLB 662, 26 (2008); Abuki, et al., PRD 78, 034034 (2008); Schaefer, et al., PRD 79, 014018 (2009); Hatta, et al., PRD 67, 014028 (2003); Cavacs, et al., PRD 77, 065016(2008); Bratovic, et al., PLB 719, 131(‘13); Bhattacharyya, et al., PRD 87,054009(‘13); Jiang, et al., PRD 88, 016008 (2013); Ke, et al., PRD 89, 074041 (2014); ⋅⋅⋅⋅⋅⋅⋅
• Lattice QCD gives smaller µEq/TE ( 0.4 ~ 1.1)
Fodor, et al., JHEP 4, 050 (2004); Gavai, et al., PRD 71, 114014 (2005); Gupta, arXiv:~0909.4630[nucl-ex]; Li, et al., PRD 84, 071503 (2011); Gupta,et al., Science 332, 1525 (2011); PRD 90, 034001 (2014); ⋅⋅⋅⋅⋅⋅
• DSE Calculations with different techniques generate different results for the µE
q/TE (0.0, 1.1 ~ 1.3, 1.4 ~ 1.6, )Blaschke, et al, PLB 425, 232 (1998); He, et al., PRD 79, 036001 (2009);Fischer, et al., PLB 702, 438 (‘11); PLB 718, 1036 (‘13); etc, Qin, Liu, et al., PRL 106, 172301(‘11); PRD 90, 034022; PRD 94, 076009; etc.
• Main physics focus of current and planed facilities; Annual International Conference on this topic; etc.
♠ General requirement for the methods used in studying QCD phase transitions
• should involve simultaneously the properties of the DCSB & its Restoration ,
the Confinement & Deconfinement ;
• should be nonperturbative QCD approach ,since the two kind PTs happen at NP QCD energy scale (102 MeV) .
♠ Theoretical Approaches:Two kinds - Continuum & Discrete (lattice)
♠ Lattice QCD:Running coupling behavior,Vacuum Structure,Temperature effect,
“Small chemical potential”;• • •
♠ Continuum:(1) Phenomenological models
(p)NJL、(p)QMC、QMF、(2) Field Theoretical
Chiral perturbation,Functional RG,QCD sum rules, Instanton(liquid) model,DS equations ,AdS/CFT,HD(T)LpQCD ,
• • • • • •5
• Dyson-Schwinger equations can play the role of a continuum approach.
Slavnov-Taylor Identity
(1) Outline of the DS Equations
axial gauges BBZ
covariant gauges
QCD
II. Dyson-Schwinger Equations— A Nonperturbative QCD Approach
C. D. Roberts, et al, PPNP 33 (1994), 477; 45-S1, 1 (2000); EPJ-ST 140(2007), 53; R. Alkofer, et. al, Phys. Rep. 353, 281 (2001); LYX, Roberts, et al., CTP 58 (2012), 79; ⋅
♠ Algorithms of Solving the DSEs of QCD
?
?
• Solving the coupled quark, ghost and gluon(parts of the diagrams) equations,e.g.,
• Solving the truncated quark equationwith the symmetries being preserved.
7
Expression of the quark gap equation• Truncation:Preserving Symm.Quark Eq.
• Decomposition of the Lorentz Structure
• Quark Eq. in Vacuum :
8
•Quark Eq. in MediumMatsubara FormalismTemperature T : Matsubara Frequency
Density ρ: Chemical Potential µ
Decomposition of the Lorentz Structure
Tnn πω )12( +=
⇒
S
S
S
S
9
Models of the eff. gluon propagator
(3)
• Commonly Used:Maris-Tandy Model (PRC 56, 3369)Cuchieri, et al, PRD, 2008
A.C. Aguilar, et al.,JHEP 1007-002
• Recently Proposed: Infrared Constant Model ( Qin, Chang, Liu, Roberts, Wilson, Phys. Rev. C 84, 042202(R), (2011). )
Taking in the coefficient of the above expression
1// 222 == ωω kt
Derivation and analysis in PRD 87, 085039 (2013) show that the one in 4-D should be infrared constant. 10
Models of quark-gluon interaction vertex
• Bare Ansatz
• Ball-Chiu (BC) Ansatz
• Curtis-Pennington (CP) Ansatz
µµ γ=Γ ),( pq (Rainbow Approx.)
• CLR (BC+ACM, Chang, etc, PRL 106,072001(‘11), Qin, etc, PLB 722,384(‘13))
Satisfying W-T Identity, L-C. restricted
Satisfying Prod. Ren.
11
(2) DSE meets the requirements for an approach to describe the QCD PTs
DCSB
In DSE approach
)()(2
2
2
)(pApBpM =
♠ Dynamical chiral symmetry breaking
Increasing the interaction strength induces the dynamical mass generation
0≠qq
K.L. Wang, YXL, et al., PRD 86,114001(‘12);
Numerical resultsin chiral limit
12
with D = 16 GeV2, ω = 0.4 GeV
Dynamical Chiral Symmetry Breaking (DCSB) still exists beyond chiral limit
Solutions of the DSE with MT model and QC model for the effective gluon propagator and bare model and 1BC model for the quark-gluon interaction vertex :
With ω = 0.4 GeV
16ξ =0.4ω =
L. Chang, Y. X. Liu, C. D. Roberts, et al, arXiv: nucl-th/0605058; R. Williams, C.S. Fischer, M.R. Pennington, arXiv: hep-ph/0612061; K. L. wang, Y. X. Liu, & C. D. Roberts, Phys. Rev. D 86, 114001 (2012).
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♠ Analyzing the spectral density function indicate that the quarks are confined at low temperature and low density
S.X. Qin, D. Rischke, Phys. Rev. D 88, 056007 (2013)
H. Chen, YXL, et al., Phys. Rev. D 78, 116015 (2008) 14
T = 0.8Tc
In MEM,
♣ Approach 1: Soliton bag model♠ Hadrons via DSE
♣ Approach 2: BSE + DSE • Mesons BSE with DSE solutions being the input
• BaryonsFadeev Equation or Diquark model (BSE+BSE)
Pressure difference provides the bag constant.
L. Chang, C.D. Roberts,PRL 103, 081601 (2009)。
Some properties of mesons in DSE-BSE Solving the 4-dimenssional covariant B-S equation with the kernel being fixed by the solution of DS equation and flavor symmetry breaking, we obtain
( L. Chang, Y. X. Liu, C. D. Roberts, et al., Phys. Rev. C 76, 045203 (2007) )
( S.X. Qin, L. Chang, Y.X. Liu, C.D. Roberts, et al., Phys. Rev. C 84, 042202(R) (2011) )
Some properties of mesons in DSE-BSE
( L. Chang, & C.D. Roberts, Phys. Rev. C 85, 052201(R) (2012) )
Present work
Wei-jie Fu, and Yu-xin Liu, Phys. Rev. D 79, 074011 (2009) ; K.L. Wang, Y.X. Liu, C.D. Roberts, Phys. Rev. D 87, 074038 (2013)
T-dependence of the screening masses of some hadrons
, when , the color gets deconfined.
GT Relation
Mσ ≅ Mπcan be a signal of the DCS.
SS Mr /1∝ mdS rr <
Hadron properties provide signals for not only the chiral phase transt. but also the confinement-deconfnmt.phase transition.
18
222 4 qMMM += πσ
Electromagnetic Property & PDF of hadronsProton electromagnetic forma factor
L. Chang et al., AIP CP 1354, 110 (‘11)P. Maris & PCT, PRC 61, 045202 (‘00)
PDF in pion PDF in kaon
R.J. Holt & C.D. Roberts, RMP 82, 2991(2010); T. Nguyan, CDR, et al., PRC 83, 062201 (R) (2011)
Decay width of ηc→γ*γ
PDF in pion PDF in kaon
J. Chen, Ming-hui Ding, Lei Chang, and Yu-xin Liu, Phys. Rev. D 95, 016010 (2017)
♠ A theoretical check on the CLR model for the quark-gluon interaction vertex
21
Dyson-Schwinger Equations
QCD
♠ A comment on the DSE approach of QCD
C. D. Roberts, et al, PPNP 33 (1994), 477; 45-S1, 1 (2000); EPJ-ST 140(2007), 53; R. Alkofer, et. al, Phys. Rep. 353, 281 (2001); LYX, et al., CTP 58, 79 (2012); ⋅⋅⋅⋅⋅⋅ .
22
III. Criteria of the Phase Transitions
! . qqcondchiralParameterOrder :
♠ Conventional Criterion
Procedure: Analyzing the TD Potential
.,,,: 2
2
2
2 signchangeetcPTofCriteriaT µ∂
Ω∂∂Ω∂
• Critical phenomenon can be a criterion for CEP
24Gao, Chen, Liu, Qin, Roberts, Schmidt, Phys. Rev. D 93, 094019 (2016).
• Locating the CEP with the Critical Behavior
25
Question:In complete nonperturbation,onecan not have the thermodynamic potential. The conventional criterion fails.One needs then new criterion!
Gao, Chen, Liu, Qin, Roberts, Schmidt, Phys. Rev. D 93, 094019 (2016).
♠ New Criterion: Chiral SusceptibilityDef.:Resp. the OP to control variables
,T
∂
∂;µ∂
∂ qq,TM∂∂ ;µ∂
∂M ,TB∂∂ ;µ∂
∂B
Simple Demonst. Equiv. of NewC to ConvC
TD Potential:
Stability Condition: 053 =++=∂Ω∂ γηβηαηη
..,0.;,053 422
2 UnstSt <>++=∂Ω∂ γηβηαη
Derivative of ext. cond. against control. var.:
we have: ( ) ( ) ( ) ( )
02
2
53
=∂Ω∂∂
Ω∂
=∂∂
=∂∂
=∂∂
++
=∂∂ −==
ηη
ζςςγ
ζςςβ
ζςςα ηηη
ζςςηχ ccc
c
( ) ( ) ( ) ( ) 0]53[ 5342 =+++++=∂
∂
=∂∂
=∂∂
=∂∂
cccc ζςςγ
ζςςβ
ζςςα
ζςςη ηηηγηβηα
;0mB
∂∂
At field theory level, seeFei Gao, Y.X. Liu,Phys. Rev. D 94, 076009 (2016) .
(刘玉鑫, 《热学》, 北京大学出版社, 2016年第1版)
♣Demonstration of the New Criterion
S.X. Qin, L. Chang, H. Chen, YXL, et al., Phys. Rev. Lett. 106, 172301 (2011).
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In chiral limit(m0 = 0)
Beyond chiral limit(m0 ≠ 0)
Fei Gao, Y.X. Liu, Phys. Rev. D 94, 076009 (2016) .
♣ Characteristic of the New Criterion
28
For multi-flavor system,one should analyze the maximal eigenvalue of thesusceptibility matrix (L.J. Jiang, YXL, et al., PRD 88, 016008),or the mixed susceptibility (F. Gao, YXL, PRD 94, 076009).
As 2nd order PT (Crossover) occurs,the χs of the two (DCS, DCSB) phases diverge (take maximum) at same states.
As 1st order PT takes place,χs of the two phases diverge at dif. states.
the χ criterion can not only give the phase boundary, but also determine the position the CEP.
♠A easily calculated criterion of the conf.General expression of the Schwinger function
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It can be positive, even if the ρ± is negative.
Fei Gao, Y.X. Liu, Phys. Rev. D 94, 076009 (2016) .
Extending D± to
0=qµ MeVq 110=µ
the consistence can be guaranteed.
♠ Viscosity to Entropy Density Ratio
viscosity to entropy density ratios can be the criterion of both the PTs
Fei Gao, Y.X. Liu, Phys. Rev. D 97, 056011 (2018) .
IV. The QCD Phase Diagrams and the position of the CEP
With bare vertex(ETP is available, the PB is shown as the dot-dashed line)
With Ball-Chiu vertex(ETP is not available, but the coexistence region is obtained)
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• In chiral limit
S.X. Qin, L. Chang, H. Chen, YXL, et al., Phys. Rev. Lett. 106, 172301 (2011).
♣ QCD Phase Diagrams and the position of the CEP
With bare vertex(ETP is available, the PB is shown as the dot-dashed line)
With CLR vertex(ETP is not available, but the coexistence region is obtained)
32
• Beyond chiral limit
F. Gao, Y.X. Liu,Phys. Rev. D 94, 076009 (2016).
The 2nd and higher order fluctuations
where
♠ A Lab Observable: BN Fluctuations
. XXX NNN −=δ
Quark number D. Avd:
33
.3, qB31 µµ == qB NNFor 2-flavor system:
Skewness & kurtosis: ., 22
4
2
3 κσσ χχ
χχ == S
Quark Number Density Fluctuations and their ratios vs T & µ in the DSE
Jing Chen, Fei Gao, Yu-xin Liu, to be published34
Quark Number Density Fluctuations vs T in the DSE
X.Y. Xin, S.X. Qin, YXL, PRD 90, 076006 (2014)35
Quark Number Density Fluctuations vs μ in the DSE
W. J. Fu, Y. X. Liu, and Y. L. Wu, Phys. Rev. D 81, 014028 (2010);X.Y. Xin, S.X. Qin, YXL, Phys. Rev. D 90, 076006 (2014)
36
Quark Number Density Fluctuations vs μ in the DSE
W. J. Fu, Y. X. Liu, and Y. L. Wu, PRD 81, 014028 (2010);X.Y. Xin, S.X. Qin, YXL, Phys. Rev. D 90, 076006 (2014)
37
In crossoverregion, the fluctuationsoscillate obviously;In 1st transt.,overlaps exist.
At CEP, they diverge!
Flavor dependence of the QN Density Fluctuations vs T in the DSE
Jing Chen, Y. X. Liu, et al., to be published. 38
The fluctuations of heavy flavor quarks are much Smaller than those of the light flavors. Net-proton fluctuations are good approx. baryon F.
Relating with Experiment Directly
Jing Chen, Fei Gao, Yu-xin Liu, arXiv: 1510.07543. 39
Chemical Freeze out Conditions
We get the T & µB of the chemical freeze-out states, in turn, the collision energy dependence of the CFO cond.
Fitting the Expt. data of & , B
B
2
1χ
χB
B
1
3χ
χ
fmL 8.2=∞=L
Relating with Experiment Directly
Jing Chen, Fei Gao, Yu-xin Liu, arXiv: 1510.07543. 40
Chemical Freeze out Conditions
FRG calculations of Wei-jie & Jan (PRD 92,116006 (‘15); PRD 93, 091501(R) (‘16), etc) also describe the data in
GeV region excellently. 6.19≥NNS
♠ A significant issue: finite size effects
Jing Chen, Fei Gao, YXL, et al., to be published.
Thermodynamical Limit: Tc (µ = 0) = 150 MeV, Tf (µ = 0) = 151 MeV,TCEP = 128 MeV,µB
CEP = 330 MeV;
L = 2.8 fm case: Tc (µ = 0) = 140 MeV, Tf (µ = 0) = 139 MeV,TCEP = 109 MeV,µB
CEP = 450 MeV;
Small ω long range in coordinate space
♠ Different methods give distinct locations of the CEP arises from diff. Conf. Length
MN model infinite range in r-spaceNJL model “zero” range in r-space Longer range Int. Smaller µE/TE
S.X. Qin, YXL, et al, PRL106,172301(‘11); X. Xin, S. Qin, YXL, PRD90,076006
ω
42
• Dynamical mass generation — DCSB;• Confinement — Positivity violation of SDF;• Hadron mass, decay, structure;
Thanks !! ♠ DSE approach is quite promising !
V. Summary & Remarks♠ Introduced the DSE of QCD briefly
• critical exponents, MeV;• susceptibilities, MeV;• BN Fluctuations, MeV.
♠Discussed criteria of the PTs & PDs in DSE)333,128(),( , =TLEBET µ)330,128(),( , ≅TLEBET µ)330,128(),( , ≅TLEBET µ
Solving quark’s DSE Quark’s Propagator
♠ Property of the matter above but near the Tc
Maximum Entropy Method (Asakawa, et al.,
PPNP 46,459 (2001);Nickel, Ann. Phys. 322,
1949 (2007)) Spectral
Function
In M-Space, only Yuan, Liu, etc, PRD 81, 114022 (2010).Usually in E-Space, Analytical continuation is required.
Qin, Chang, Liu, et al., PRD 84, 014017(2011)
T = 3.0Tc
Disperse Relation and Momentum Dependence of the Residues of the Quasi-particles’ poles
T = 1.1Tc
S.X. Qin, L. Chang, Y.X. Liu, et al., Phys. Rev. D 84, 014017(2011); F. Gao, S.X. Qin, Y.X. Liu, et al., Phys. Rev. D 89, 076009 (2014).
Normal T. Mode
Plasmino M.
Zero Mode
♣ The zero mode exists at low momentum (<7.0Tc), and is long-range correlation (λ ~ ω−1 >λFP) .
♣ The quark at the T where DCS has been restored involves still rich phases. And the matter is sQGP.
J.-P. Blaizot, et al., PRL 83, 2906
♠ Consistence with Thermodynamic Evolution
Crossover Region First Order Region
柯伟尧, et al., PRD 89, 074041(‘14), 高飞, et al., PRD 94, 094030 (2016)
Chiral Symmetry Breaking generates the Anomalous Magnetic Moment of Quark
L. Chang, Y.X. Liu, & C.D. Roberts, PRL 106, 072001 (‘11)
Consequently, nucleon has anomalous magnetic moment.
♠ Density & Temperature Dependence of some Properties of Nucleon in DSE Soliton Model
0/ BB 0/ RR0/ MM (Y. X. Liu, et al.,
NP A 695, 353 (2001);
NPA 725,127 (2003);
NPA 750, 324 (2005) )
( Y. Mo, S.X. Qin, and Y.X. Liu, Phys. Rev. C 82, 025206 (2010) )
♠ Key Issue 2: Interface effects• Interface tension between the DCS-unconf. phase and the DCSB-confined phase With the scheme (J. Randrup, PRC 79, 054911 (2009) )
we have
with
and (EoM)
,)()()( 2212
21 nCnnCnrF ∇+≅⋅⋅⋅⋅⋅⋅+∇+= µµr
),()( nFnFF MTT −=∆
)()()( )()(Lnn
nFnFLTM nnnFnF
LH
LTHT −+= −−
.0)( 221 =+∆ ∂
∂rn
T CF,)()( 2
21 ∫∫
+∞
∞− ∂∂
+∞
∞−−=∆= dxCdxFT r
nTγ
∫ ∆= H
L
n
n TC dnnF )(2
• Interface tension between the DCS-unconf. phase and the DCSB-confined phase
Parameterized as
with parameters
Fei Gao, & Yu-xin Liu,Phys. Rev. D 94, 094030 (2016)
• Effects of the Interfacee.g., Solving the entropy puzzle
In thermodynamical limit
With the interface entropy density
being included, we have
VATAs )( ∂∂−= γ
Fei Gao, & Y.X. Liu,Phys. Rev. D 94, 094030 (2016)
••••••
Ⅲ. Thermal Properties
Pressure
Sound Speed
♠ Basic Formulae & Algorithm:
52
Heat capability & latent heat
Entropy Density ,
, .
Energy Density ,
♠ Trace Anomaly at Zero Chemical Potential
53
TM = 140 MeV
Gao, Chen, Liu, Qin, Roberts, Schmidt, Phys. Rev. D 93, 094019 (2016).
♠ Pressure & Trace Anomaly at Non-Zero Chemical Potential
54
TM = 140 MeV
Gao, Chen, Liu, Qin, Roberts, Schmidt, Phys. Rev. D 93, 094019 (2016).
♠ Sound Speed squared
55
TM = 140 MeV
Gao, Chen, Liu, Qin, Roberts, Schmidt, Phys. Rev. D 93, 094019 (2016).
♠ Specific heat capability & Latent heat
56
TM = 140 MeV
Gao, Chen, Liu, Qin, Roberts, Schmidt, Phys. Rev. D 93, 094019 (2016).
♠ Entropy
57
Only the UniformPart
Including the surface Partwith
Fei Gao, Y.X. Liu, Phys. Rev. D 94, 094030 (2016)
TAs ∂∂−= γ
Entropy puzzle !
♠ An Astronomical Observable: Gravitational Mode Oscillation Frequency
• G-Wave in Newly Born Compact Star (NS, QS)
• G-Wave in Binary Neutron Star MergerFpostmerger
∈(1.84, 3.73)kHz,with width<200Hz,(PRD 86, 063001(2012))Fspiral < Fpostmerger
• Comparison of G-mode Oscillation Frequencies of the two kind nb Stars
W.J. Fu, H.Q. Wei, and Y.X. Liu, arXiv: 0810.1084, Phys. Rev. Lett. 101, 181102 (2008)
Neutron Star: RMF, Quark Star: Bag ModelFrequency of the G-mode oscillation
• Comparison with other modes
W.J. Fu, Z. Bai, Y.X. Liu, arXve:1701.00418♣ G-mode oscillation in quark star has very low freq. !
Neutron Star: RMF, Quark Star: Bag ModelFrequencies of the f- & p-mode oscillations
• Taking into account the DCSB effect
• Work in the DS equation scheme is under progress.(Zhan BAI)